CN220774124U - Multi-slide rail adjustable iron core lamination table - Google Patents

Abstract

The utility model relates to an adjustable iron core lamination table with multiple sliding rails, which is structurally characterized in that a plurality of base sliding rails A are arranged on the top surface of a table top in parallel, a plurality of base sliding rails B which are perpendicular to the base sliding rails A are connected to the base sliding rails A in a sliding manner through sliding rail connecting pieces to provide a displacement rail for the lamination table, a plurality of base clamping sleeves are respectively connected to each base sliding rail in a sliding manner, a limiting mechanism for clamping a pull plate is rotatably connected to each base clamping sleeve, the limiting mechanism comprises a porous limiting block, the center of the porous limiting block is rotatably connected to the sliding rail connecting pieces, a left bolt hole and a right bolt hole are formed in the porous limiting block, clamping groove limiting insertion plates are respectively arranged on the left side and the right side of the porous limiting block, and bolts of the two side clamping groove limiting insertion plates penetrate through the bolt holes at corresponding positions of the porous limiting blocks and are inserted into the through holes of the other clamping groove limiting insertion plates. The two groups of base sliding rails can accurately limit the pull plate, control the quality of the swing table and improve the swing table efficiency.

Description

Multi-slide rail adjustable iron core lamination table

Technical Field

The utility model relates to a multi-slide rail adjustable iron core lamination table, and belongs to the technical field of transformer iron core manufacturing.

Background

Before lamination of the transformer iron core, the transformer iron core needs to be subjected to swing operation on a lamination table, and iron core clamping pieces, pulling plates and other parts are placed to a designated position according to the size and the type of the iron core so as to be subjected to iron core lamination operation by lamination personnel.

The lamination table in the prior art generally does not have an accurate positioning function, lacks limit control on the pull plate, is easy to occur in the conditions of pulling the plate and deviating from a designated position, can influence the quality of a finished iron core, or causes efficiency loss by repeated adjustment of the lamination table by lamination staff.

Disclosure of Invention

The utility model provides a multi-slide rail adjustable iron core lamination table, which aims to overcome the defects in the prior art, realize accurate limiting of clamping parts and improve the table arranging efficiency.

The technical solution of the utility model is as follows: the utility model provides a core lamination platform with adjustable many slide rails, its structure includes the desktop, be equipped with a plurality of A base slide rail on the desktop top surface in parallel, a plurality of B base slide rail looks vertically with A base slide rail is on A base slide rail through slide rail connecting piece sliding connection, provide displacement track for the lamination platform, sliding connection has a plurality of base cutting ferrule on every B base slide rail respectively, rotatable coupling has a stop gear who is used for pressing from both sides tight arm-tie on every base cutting ferrule, stop gear includes porous stopper, porous stopper center rotatable coupling is on slide rail connecting piece, open on the porous stopper has the bolt hole of lining up about, porous stopper left and right sides is equipped with draw-in groove spacing picture peg respectively, be equipped with bolt and through-hole on the draw-in groove spacing picture peg, the bolt of the spacing picture peg of both sides draw-in groove passes porous stopper corresponds the position bolt hole and inserts in the through-hole of another draw-in groove spacing picture peg. The arrangement of the two groups of base sliding rails can accurately limit the pulling plate, control the quality of the swing table and improve the swing table efficiency.

Preferably, the two pairs of bolt holes are arranged, and each clamping groove limiting plugboard is provided with a pair of bolts and a pair of through holes, so that the effective width of the limiting mechanism can be adjusted.

Preferably, the front side and the rear side of the porous limiting block are also provided with threaded holes extending into the bolt holes and are in threaded connection with locking screws, and the limiting mechanism with the adjustable width can be fixed in position.

Preferably, the front and back edges of the top surface of the desktop are provided with a pair of C base sliding rails which are parallel to each other, bottoms of two ends of a D base sliding rail which are parallel to each other and are vertical to the C base sliding rails on the horizontal plane are connected to the C base sliding rails on the two sides through sliding rail connecting pieces in a sliding manner, each D base sliding rail is connected with a channel steel which is arranged along the length direction of the D base sliding rail in a sliding manner, the channel steel is used as a temporary iron core clamping piece, the A base sliding rail and the B base sliding rail are positioned between the C base sliding rail and the D base sliding rail, the D base sliding rail is parallel to the A base sliding rail, and the C base sliding rail is parallel to the B base sliding rail.

Preferably, the number of the base sliding rails A is two, and the number of the base sliding rails B is three.

Preferably, the lifting mechanism further comprises a lifting mechanism, the lifting mechanism comprises a stud connected to the top of the base clamping sleeve, the stud is connected with a hexagonal jacking column in a threaded manner, the top of the hexagonal jacking column is provided with a limiting column, the jacking column clamping sleeve is sleeved on the top of the hexagonal jacking column and the limiting column, the top of the jacking column clamping sleeve is provided with a stepped hole, the top of the hexagonal jacking column and the limiting column are accommodated in the stepped hole, and the top of the limiting column protrudes out of the top of the stepped hole and is rotationally connected with the center of the porous limiting block. The multi-point adjustment and control of the levelness of the lamination table can be realized by combining the lifting mechanism, the lamination level can be controlled, the compatibility of the lamination table can be widened, and the multi-model iron core sharing lamination table can be realized.

The utility model has the advantages that: structural design is reasonable, and accessible realizes pressing from both sides the accurate spacing of accessory and realizes the quality control of iron core lamination front pendulum platform, compares in prior art structure, can improve the pendulum platform quality of iron core, improves lamination process and assembly process's stability, improves lamination personnel's work efficiency, can reduce simultaneously by the unstable product performance loss that leads to of lamination quality.

Drawings

Fig. 1 is a schematic structural view of an embodiment of a multi-rail adjustable core lamination stage according to the present utility model.

Fig. 2 is a schematic view of the placement of the pulling plate of fig. 1.

Fig. 3 is a schematic structural view of the sliding lifting limiting mechanism in fig. 1.

Fig. 4 is an exploded view of fig. 3.

Fig. 5 is a perspective view showing the connection state of the jack post clamping sleeve, the hexagonal jack posts and the limit posts in fig. 3.

Fig. 6 is a schematic view of an embodiment of a multi-rail adjustable core lamination stage of the present utility model applied to a maximum size core.

Fig. 7 is a schematic view of an embodiment of the multi-rail adjustable core lamination stage of the present utility model in use when applied to a medium-sized core.

Fig. 8 is a schematic view of an embodiment of a multi-rail adjustable core lamination stage of the present utility model in use when applied to a minimum specification core.

In the figure, channel steel is 1, a D base sliding rail is 2', an A base sliding rail is 2', a C base sliding rail is 3, a B base sliding rail is 3', a base clamping sleeve is 4, a jack post clamping sleeve is 5, a sliding rail connecting piece is 6, a clamping groove limiting inserting plate is 7, a pulling plate is 8, a porous limiting block is 9, a hexagonal jack post is 10, a locking screw is 11, a limiting post is 12, and a tabletop is 13.

Detailed Description

The present utility model will be described in further detail with reference to examples and embodiments.

As shown in fig. 1-5, an adjustable iron core lamination table with multiple sliding rails structurally comprises a tabletop 13 for placing the lamination table, a pair of parallel C base sliding rails 3 are arranged at the front and rear edges of the top surface of the tabletop 13, a pair of parallel D base sliding rails 2 which are perpendicular to the C base sliding rails 3 on the horizontal plane are connected to the C base sliding rails 3 in a sliding manner through sliding rail connectors, a pair of a base sliding rails 2' are arranged on the top surface of the tabletop 13 between the D base sliding rails 2 in parallel, three B base sliding rails 3' which are parallel to the C base sliding rails 3 are connected to the two a base sliding rails 2' in a sliding manner through sliding rail connectors 6, and the D base sliding rails 2, the C base sliding rails 3, the a base sliding rails 2' and the B base sliding rails 3' provide displacement rails for the lamination table.

And each D base sliding rail 2 is connected with a channel steel 1 which is arranged along the length direction of the D base sliding rail 2 in a sliding manner and is used as a temporary iron core clamping piece.

And a plurality of lifting limiting mechanisms are slidably connected to each B base sliding rail 3', and each lifting limiting mechanism comprises a lifting mechanism for adjusting the levelness of the pull plate 8 and a limiting mechanism for clamping the pull plate 8.

The lifting mechanism comprises a base clamping sleeve 4 which is in sliding connection with a base sliding rail 3' B, a stud is connected to the top of the base clamping sleeve 4, a hexagonal jack post 10 used for height regulation and control is connected to the stud through threads, a limit post 12 is arranged at the top of the hexagonal jack post 10, the jack post clamping sleeve 5 is sleeved on the top end of the hexagonal jack post 10 and the limit post 12, a stepped hole is arranged at the top of the jack post clamping sleeve 5, the top end of the hexagonal jack post 10 and the limit post 12 are accommodated in the stepped hole, the top end of the limit post 12 protrudes out of the top of the stepped hole and is rotationally connected with the center of a porous limiting block 9, two pairs of mutually parallel bolt holes which are communicated left and right are formed in the porous limiting block 9, clamping groove limiting plug plates 7 are respectively arranged on the left side and the right side of the porous limiting block 9, a pair of clamping groove limiting plug plates 7 are used for limiting a pull plate 8, the pull plate 8 is used for supporting and clamping at the position of the core post, a pair of bolts and a pair of through holes are arranged on the clamping groove limiting plug plate 7, the bolts penetrate through the corresponding position of the porous limiting plug holes of the porous limiting plug plates 9 and are inserted into through holes of the other clamping groove limiting plug plates 7, so that the positioning connection is realized, the positioning and the positioning limiting plug 9 is also provided with two sides extending to the pin holes and the front and back sides and the porous limiting plug 9 are connected with the pin holes 11, and the threaded limiting bolts are connected to the threaded limiting bolts 11 and the threaded limiting plug 7 and the locking bolts 11.

According to the structure, when the iron core yoke is in operation, the standard position of the swinging table is determined according to parameters such as the length and the width of the iron core yoke, the side columns and the middle column, and the base sliding rails are adjusted to the designated positions. And the base clamping sleeve 4 is installed and is uniformly distributed on the base sliding rail 3' by sliding. The hexagonal jack post 10 is installed, the limiting post 12 is installed in the jack post clamping sleeve 5, the jack post clamping sleeve 5 is sleeved on the hexagonal jack post 10, and the porous limiting block 9 and the clamping groove limiting plug board 7 are installed. The level bar measures the levelness of the lamination table and carries out horizontal adjustment by rotating the hexagonal jack post 10. After the horizontal adjustment is completed, the pull plate 8 is placed on the porous limiting block 9, and the pull plate 8 is clamped by moving the clamping groove limiting plug plate 7. And the locking screw 11 is rotated to fasten the clamping groove limiting plugboard 7, so that the core lamination front swinging table operation is completed.

The lamination table can meet the installation and use requirements of iron cores of various specifications, and is described by the following 3 embodiments.

Example 1

As shown in fig. 6, when the iron core is maximum, the whole lamination table is covered, a pull plate 8 is clamped on each B base sliding rail 3 'along the length direction, and the pull plates 8 are clamped in all the limiting mechanisms on the corresponding B base sliding rails 3' for supporting the middle part of the iron core, and the channel steels 1 on the two D base sliding rails 2 support the two side yokes of the iron core.

Example 2

As shown in fig. 7, when the iron core specification is smaller than that of the embodiment 1, the yoke on one side of the iron core is supported by the channel steel 1 on the base slide rail 2 on one side through the pull plate 8, the yoke on the other side of the iron core is supported by the pull plate 8 parallel to the base slide rail 2 on the other side of the iron core, the pull plate 8 is clamped in a limiting mechanism on each base slide rail 3 'on the outermost side far away from the yoke on one side of the iron core, and the remaining limiting mechanisms on each base slide rail 3' on the other base slide rail 3 'are respectively clamped with one pull plate 8 along the length direction of the base slide rail 3' for supporting the middle part of the iron core.

Example 3

As shown in fig. 8, when the iron core specification is the smallest compared with the embodiments 1 and 2, the two side D base slide rails 2 are not used, the two side yokes of the iron core are respectively supported on a pull plate 8 parallel to the D base slide rails 2, the pull plate 8 is clamped in a limiting mechanism at the outermost end of the same side on each B base slide rail 3', and the remaining limiting mechanisms on each B base slide rail 3' are respectively clamped with a pull plate 8 along the length direction of the B base slide rail 3' for supporting the middle part of the iron core.

The above components are all of the prior art, and any model and existing design that can achieve their corresponding functions can be used by those skilled in the art.

The foregoing is merely a preferred embodiment of the present utility model, and it should be noted that modifications and improvements could be made by those skilled in the art without departing from the inventive concept, which falls within the scope of the present utility model.

Claims (6)

1. The utility model provides a core lamination platform with adjustable many slide rails, a serial communication port, including desktop (13), be equipped with a plurality of A base slide rail (2 ') on desktop (13) top surface in parallel, a plurality of B base slide rail (3 ') that are perpendicular with A base slide rail (2 ') pass through slide rail connector (6) sliding connection on A base slide rail (2 '), sliding connection has a plurality of base cutting ferrule (4) on every B base slide rail (3 ') respectively, rotatable coupling has a stop gear who is used for pressing from both sides tight arm-tie (8) on every base cutting ferrule (4), stop gear includes porous stopper (9), porous stopper (9) central swivelling joint is on slide rail connector (6), open on porous stopper (9) has the bolt hole of lining up about, the left and right sides of porous stopper (9) are equipped with draw-in groove limiting insert plate (7) respectively, be equipped with bolt and through-hole on the draw-in groove limiting insert plate (7), the bolt of the corresponding position of porous stopper (9) of both sides draw-in groove limiting insert plate (7) is passed and is inserted and is established in the through-hole of another draw-in groove limiting insert plate (7).

2. A multi-slide adjustable core lamination table as claimed in claim 1, wherein two pairs of pin holes are provided, and each slot limiting insert plate (7) is provided with a pair of pins and a pair of through holes.

3. A multi-slide-rail adjustable core lamination table as claimed in claim 2, characterized in that the front and rear sides of the multi-hole limiting block (9) are further provided with threaded holes extending into the bolt holes and are in threaded connection with locking screws (11).

4. The adjustable iron core lamination table with multiple sliding rails as claimed in claim 1, wherein a pair of parallel C base sliding rails (3) are arranged at the front and rear edges of the top surface of the table top (13), bottoms of two ends of a pair of parallel D base sliding rails (2) which are perpendicular to the C base sliding rails (3) on a horizontal plane are slidably connected to the C base sliding rails (3) on two sides through sliding rail connectors, a channel steel (1) arranged along the length direction of the D base sliding rails (2) is slidably connected to each D base sliding rail (2), the a base sliding rail (2 ') and the B base sliding rail (3') are located between the C base sliding rails (3) and the D base sliding rails (2), the D base sliding rails (2) are parallel to the a base sliding rails (2 '), and the C base sliding rails (3) are parallel to the B base sliding rails (3').

5. A multi-rail adjustable core lamination table as defined in claim 1, wherein the number of a base rails (2 ') is two and the number of B base rails (3') is three.

6. The multi-slide-rail adjustable iron core lamination table according to claim 1, further comprising a lifting mechanism, wherein the lifting mechanism comprises a stud connected to the top of the base clamping sleeve (4), a hexagonal jacking column (10) is connected to the stud in a threaded mode, a limiting column (12) is arranged at the top of the hexagonal jacking column (10), the jacking column clamping sleeve (5) is sleeved on the top end of the hexagonal jacking column (10) and the limiting column (12), a stepped hole is formed in the top of the jacking column clamping sleeve (5), the top end of the hexagonal jacking column (10) and the limiting column (12) are accommodated in the stepped hole, and the top end of the limiting column (12) protrudes out of the top of the stepped hole and is connected with the center of the porous limiting block (9) in a rotating mode.